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1. Penetrating chest injury

Author

Santiago Quintero‐Vanegas and Valentina Cartagena Sierra

Subjects
Medical emergencies. Critical care. Intensive care. First aid, RC86-88.9
Published
2023
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5. Glacial Southern Ocean Expansion Recorded in Foraminifera-Bound Nitrogen Isotopes From the Agulhas Plateau During the Mid-Pleistocene Transition

Author

Marcks, B. A., Dos Santos, T. P., Lessa, D. V.O., Cartagena-Sierra, A., Berke, M. A., Starr, A., Hall, I. R., Kelly, R. P., Robinson, Rebecca S., Marcks, B. A., Dos Santos, T. P., Lessa, D. V.O., Cartagena-Sierra, A., Berke, M. A., Starr, A., Hall, I. R., Kelly, R. P., and Robinson, Rebecca S.

Abstract

The emergence of 100-Kyr glacial cycles (The Mid-Pleistocene Transition [MPT]) is attributed in part to slower global overturning circulation and iron stimulation of biological carbon drawdown in the Southern Ocean. We present foraminifera-bound nitrogen isotope values and polar planktic foraminifera abundances from the Agulhas Plateau that show that increases in biogenic sediment accumulation coincide with northward migrations of the Subtropical Frontal Zone (STFZ) and elevated foraminifera-bound nitrogen isotope values during MPT glacial episodes. The nitrogen isotope values of two planktic foraminifera species, Globigerina bulloides and Globorotalia inflata show remarkable coherence amongst the sea surface temperature gradient between the STFZ and SAZ, and polar foraminifera abundances, indicating a strong relationship between nitrogen isotope dynamics above the Agulhas Plateau and migrations of the STFZ. Northward migration of the STFZ may have been essential to prolonging glacial intervals by increasing deep ocean carbon storage via a northward shift of the South Westerly Winds and a reduction in upwelling, delivery of fresher surface waters into the upper limb of global overturning circulation, or inhibiting heat and salt delivery to the Atlantic as Agulhas Leakage.

Published
2023

8. Site U1474

Author

Hall, I.R., primary, Hemming, S.R., additional, LeVay, L.J., additional, Barker, S., additional, Berke, M.A., additional, Brentegani, L., additional, Caley, T., additional, Cartagena-Sierra, A., additional, Charles, C.D., additional, Coenen, J.J., additional, Crespin, J.G., additional, Franzese, A.M., additional, Grüetzner, J., additional, Han, X., additional, Hines, S.K.V., additional, Jimenez-Espejo, F.J., additional, Just, J., additional, Koutsodendris, A., additional, Kubota, K., additional, Lathika, N., additional, Norris, R.D., additional, Periera dos Santos, T., additional, Robinson, R., additional, Rolinson, J.M., additional, Simon, M.H., additional, Tangunan, D., additional, van der Lubbe, J.J.L., additional, Yamane, M., additional, and Zhang, H., additional

Published
2017
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9. Expedition 361 methods

Author

Hall, I.R., primary, Hemming, S.R., additional, LeVay, L.J., additional, Barker, S., additional, Berke, M.A., additional, Brentegani, L., additional, Caley, T., additional, Cartagena-Sierra, A., additional, Charles, C.D., additional, Coenen, J.J., additional, Crespin, J.G., additional, Franzese, A.M., additional, Gruetzner, J., additional, Han, X., additional, Hines, S.K.V., additional, Jimenez Espejo, F.J., additional, Just, J., additional, Koutsodendris, A., additional, Kubota, K., additional, Lathika, N., additional, Norris, R.D., additional, Periera dos Santos, T., additional, Robinson, R., additional, Rolinson, J.M., additional, Simon, M.H., additional, Tangunan, D., additional, van der Lubbe, J.J.L., additional, Yamane, M., additional, and Zhang, H., additional

Published
2017
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10. Expedition 361 summary

Author

Hall, I.R., primary, Hemming, S.R., additional, LeVay, L.J., additional, Barker, S., additional, Berke, M.A., additional, Brentegani, L., additional, Caley, T., additional, Cartagena-Sierra, A., additional, Charles, C.D., additional, Coenen, J.J., additional, Crespin, J.G., additional, Franzese, A.M., additional, Gruetzner, J., additional, Han, X., additional, Hines, S.K.V., additional, Jimenez Espejo, F.J., additional, Just, J., additional, Koutsodendris, A., additional, Kubota, K., additional, Lathika, N., additional, Norris, R.D., additional, Periera dos Santos, T., additional, Robinson, R., additional, Rolinson, J.M., additional, Simon, M.H., additional, Tangunan, D., additional, van der Lubbe, J.J.L., additional, Yamane, M., additional, and Zhang, H., additional

Published
2017
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11. Persistent influence of precession on northern ice sheet variability since the early Pleistocene

Author

STEPHEN BARKER, AIDAN STARR, JEROEN VAN DER LUBBE, Alice Doughty, Gregor Knorr, Stephen Conn, Sian Lordsmith, Lindsey Owen, Alexandra Nederbragt, Sidney Hemming, Ian Hall, Leah Levay, Melissa Berke, Luna Brentegani, Thibault Caley, Alejandra Cartagena-Sierra, Christopher Charles, Jason James Coenen, Julian Crespin, Allison Franzese, Jens Gruetzner, Xibin Han, Sophie Hines, Francisco Jimenez-Espejo, Janna Just, Andreas Koutsodendris, Kaoru Kubota, Lathika N., Richard Norris, Thiago Periera dos Santos, Rebecca Robinson, John Rolison, Margit Simon, Deborah Tangunan, Masako Yamane, Hucai Zhang, and Geology and Geochemistry

Subjects
Multidisciplinary
Abstract

Prior to ~1 million years ago (Ma), variations in global ice volume were dominated by changes in obliquity; however, the role of precession remains unresolved. Using a record of North Atlantic ice rafting spanning the past 1.7 million years, we find that the onset of ice rafting within a given glacial cycle (reflecting ice sheet expansion) consistently occurred during times of decreasing obliquity whereas mass ice wasting (ablation) events were consistently tied to minima in precession. Furthermore, our results suggest that the ubiquitous association between precession-driven mass wasting events and glacial termination is a distinct feature of the mid to late Pleistocene. Before then (increasing), obliquity alone was sufficient to end a glacial cycle, before losing its dominant grip on deglaciation with the southward extension of Northern Hemisphere ice sheets since ~1 Ma.

Published
2022
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12. Latitudinal Migrations of the Subtropical Front at the Agulhas Plateau Through the Mid‐Pleistocene Transition

Author

Aidan Starr, Leah J. LeVay, Basia Marcks, Melissa A. Berke, Sidney R. Hemming, Isla S. Castañeda, Ian Hall, t. Expedition Scientific Party, A. Cartagena-Sierra, and Rebecca S. Robinson

Subjects
Atmospheric Science, geography, Plateau, geography.geographical_feature_category, Pleistocene, Ocean current, Paleontology, Westerlies, Oceanography, Sea surface temperature, Water column, Subtropical front, Southern Hemisphere, Geology
Abstract

The meridional variability of the Subtropical Front (STF) in the Southern Hemisphere, linked to expansions or contractions of the Southern Ocean, may have played an important role in global ocean circulation by moderating the magnitude of water exchange at the Indian-Atlantic Ocean Gateway, so called Agulhas Leakage. Here we present new biomarker records of upper water column temperature ( and ) and primary productivity (chlorins and alkenones) from marine sediments at IODP Site U1475 on the Agulhas Plateau, near the STF and within the Agulhas retroflection pathway. We use these multiproxy time-series records from 1.4 to 0.3 Ma to examine implied changes in the upper oceanographic conditions at the mid-Pleistocene transition (MPT, ca. 1.2?0.8 Ma). Our reconstructions, combined with prior evidence of migrations of the STF over the last 350 ka, suggest that in the Southwestern Indian Ocean the STF may have been further south from the Agulhas Plateau during the mid-Pleistocene Interim State (MPIS, MIS 23?12) and reached its northernmost position during MIS 34?24 and MIS 10. Comparison to a Globorotalia menardii-derived Agulhas Leakage reconstruction from the Cape Basin suggests that only the most extreme northward migrations of the STF are associated with reduced Agulhas Leakage. During the MPIS, STF migrations do not appear to control Agulhas Leakage variability, we suggest previously modeled shifting westerly winds may be responsible for the patterns observed. A detachment between STF migrations and Agulhas Leakage, in addition to invoking shifting westerly winds may also help explain changes in CO2 ventilation seen during the MPIS.

Published
2021
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13. Controls on leaf wax fractionation and δ2H values in tundra vascular plants from western Greenland

Author

Melissa A. Berke, Darren Cheah, Alejandra Cartagena Sierra, Rosemary T. Bush, and Keith F O'Connor

Subjects
Empetrum, Betula nana, 010504 meteorology & atmospheric sciences, biology, 010502 geochemistry & geophysics, biology.organism_classification, 01 natural sciences, Tundra, Geochemistry and Petrology, Aquatic plant, Lipid biosynthesis, Botany, Equisetum arvense, Salix glauca, Environmental science, Arctic vegetation, 0105 earth and related environmental sciences
Abstract

Hydrogen isotope ratios of leaf waxes are used to reconstruct past hydroclimate because they are a reflection of meteoric water, but the interpretation of these signatures from ancient sedimentary archives relies on a thorough understanding of the drivers of modern isotope variability and controls on fractionation. These studies are particularly valuable in the high latitudes, regions especially vulnerable to rapid climate change and increasingly used for plant-based proxy reconstructions of past hydroclimate, but also where modern vegetation is understudied compared to the lower latitudes. Here we investigate δ2H values from leaf wax n-alkanes of vascular tundra plants in the Kangerlussuaq area of western Greenland. We collected a variety of common tundra species to study possible interspecies variability in δ2H values including dwarf shrubs (Betula nana, Empetrum hermaphroditum, Salix glauca), forbs and graminoids (Vaccinium uliginosum, Rhododendron tomentosum, and Calamagrostis lapponica), a horsetail species (Equisetum arvense), and a submerged aquatic macrophyte from a local lake (Stuckenia filiformis). Using previously measured leaf and stem waters to help constrain potential drivers of leaf wax n-alkane δ2H values, we find that the overall net fractionation (eapp) from the studied species is −75 ± 20‰. The eapp at Kangerlussuaq is consistent with other studies of Arctic vegetation that find smaller eapp than from the majority of lower latitude sites. The fractionation of leaf water and xylem water (elw/xw) and the fractionation of xylem water and precipitation (exw/p) are both relatively constant, suggesting stable leaf and soil related fractionations across species. Estimates of biosynthetic fractionation (ebio), as evidenced from the fractionation of the δ2H values of n-alkanes and leaf water (ewax/lw), are not constant across species as sometimes assumed, and are small (average of ebio is −120 ± 27‰) compared to many published estimates. This supports a significant role in ebio shaping the eapp in this high latitude setting, where lipid biosynthesis may be driving differences in n-alkane δ2H values. This finding suggests that lipids in the Kangerlussuaq plants studied rely on the use of some proportion of different hydrogen sources during lipid synthesis, such as stored NADPH. The cumulative results of this survey of Kangerlussuaq area n-alkane δ2H values and water-wax fractionations suggest that fractionation in the high latitudes during the short summer growing season may play an important role in governing the small eapp compared to many low latitude sites. Better understanding of appropriate eapp and the importance of ebio in controlling plant wax fractionation from the high latitudes is necessary for future reconstructions of hydroclimate using leaf wax δ2H values in these regions.

Published
2019
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14. Latitudinal Migrations of the Subtropical Front at the Agulhas Plateau Through the Mid-Pleistocene Transition

Author

Alejandra Cartagena-Sierra, Melissa Berke, Rebecca Robinson, Basia Marcks, Isla S. Castañeda, Aidan Starr, Ian R. Hall, Sidney R. Hemming, Leah J. LeVay, Stephen Barker, Luna Brentegani, Thibault Caley, Christopher Charles, Jason James Coenen, Julian Crespin, Allison Franzese, Jens Gruetzner, Xibin Han, Sophie Hines, Francisco Jimenez-Espejo, Janna Just, Andreas Koutsodendris, Kaoru Kubota, Lathika N., Richard Norris, Thiago Periera dos Santos, John Rolison, Margit Simon, Deborah Tangunan, Jeroen van der Lubbe, Masako Yamane, and Hucai Zhang

Abstract

The meridional variability of the Subtropical Front (STF) in the Southern Hemisphere, linked to expansions or contractions of the Southern Ocean, may have played an important role in global ocean circulation by moderating the magnitude of water exchange at the Indian-Atlantic Ocean Gateway, so called Agulhas Leakage. Here we present new biomarker records of upper water column temperature (and) and primary productivity (chlorins and alkenones) from marine sediments at IODP Site U1475 on the Agulhas Plateau, near the STF and within the Agulhas retroflection pathway. We use these multiproxy time-series records from 1.4 to 0.3Ma to examine implied changes in the upper oceanographic conditions at the mid-Pleistocene transition (MPT, ca. 1.2–0.8Ma). Our reconstructions, combined with prior evidence of migrations of the STF over the last 350 ka, suggest that in the Southwestern Indian Ocean the STF may have been further south from the Agulhas Plateau during the mid-Pleistocene Interim State (MPIS, MIS 23–12) and reached its northernmost position during MIS 34–24 and MIS 10. Comparison to aGloborotalia menardii-derived Agulhas Leakage reconstruction from the Cape Basin suggests that only the most extreme northward migrations of the STF are associated with reduced Agulhas Leakage. During the MPIS, STF migrations do not appear to control Agulhas Leakage variability, we suggest previously modeled shifting westerly winds may be responsible for the patterns observed. A detachment between STF migrations and Agulhas Leakage, in addition to invoking shifting westerly winds may also help explain changes in CO2ventilation seen during the MPIS.

Published
2021

15. Antarctic icebergs reorganize ocean circulation during Pleistocene glacials

Author

Starr, Aidan, Hall, Ian R., Barker, Stephen, Rackow, Thomas, Zhang, Xu, Hemming, Sidney R., van der Lubbe, H. J.L., Knorr, Gregor, Berke, Melissa A., Bigg, Grant R., Cartagena-Sierra, Alejandra, Jiménez-Espejo, Francisco J., Gong, Xun, Gruetzner, Jens, Lathika, Nambiyathodi, LeVay, Leah J., Robinson, Rebecca S., Ziegler, Martin, Expedition 361 Science Party, Stratigraphy and paleontology, and Stratigraphy & paleontology

Subjects
General
Abstract

The dominant feature of large-scale mass transfer in the modern ocean is the Atlantic meridional overturning circulation (AMOC). The geometry and vigour of this circulation influences global climate on various timescales. Palaeoceanographic evidence suggests that during glacial periods of the past 1.5 million years the AMOC had markedly different features from today1; in the Atlantic basin, deep waters of Southern Ocean origin increased in volume while above them the core of the North Atlantic Deep Water (NADW) shoaled2. An absence of evidence on the origin of this phenomenon means that the sequence of events leading to global glacial conditions remains unclear. Here we present multi-proxy evidence showing that northward shifts in Antarctic iceberg melt in the Indian–Atlantic Southern Ocean (0–50° E) systematically preceded deep-water mass reorganizations by one to two thousand years during Pleistocene-era glaciations. With the aid of iceberg-trajectory model experiments, we demonstrate that such a shift in iceberg trajectories during glacial periods can result in a considerable redistribution of freshwater in the Southern Ocean. We suggest that this, in concert with increased sea-ice cover, enabled positive buoyancy anomalies to ‘escape’ into the upper limb of the AMOC, providing a teleconnection between surface Southern Ocean conditions and the formation of NADW. The magnitude and pacing of this mechanism evolved substantially across the mid-Pleistocene transition, and the coeval increase in magnitude of the ‘southern escape’ and deep circulation perturbations implicate this mechanism as a key feedback in the transition to the ‘100-kyr world’, in which glacial–interglacial cycles occur at roughly 100,000-year periods.

Published
2021

16. The interglacial-glacial sequence of events at the Agulhas Plateau: Antarctic icebergs lead ocean circulation into ice ages and across the Mid-Pleistocene Transition

Author

A. Cartagena-Sierra, Gregor Knorr, Martin Ziegler, Thomas Rackow, J.J.L. van der Lubbe, Aidan Starr, Francisco J. Jiménez-Espejo, Sidney R. Hemming, Xu Zhang, Nambiyathodi Lathika, Melissa A. Berke, Leah J. LeVay, Jens Gruetzner, Xun Gong, Stephen Barker, Grant R. Bigg, and Ian Hall

Subjects
geography, Oceanography, Plateau, geography.geographical_feature_category, Pleistocene, Interglacial, Ocean current, North Atlantic Deep Water, Ice age, Glacial period, Geology, Iceberg
Abstract

Palaeoceanographic evidence suggests that glacial periods of the Mid to Late Pleistocene were characterized by markedly different global ocean circulation patterns to modern; in the Atlantic basin, deep waters of Southern Ocean origin increased in volume while above them the core of the North Atlantic Deep Water (NADW) shoaled. Whilst proxy records and modelling efforts continue to clarify this picture, an evidence alluding to the origin of this phenomenon remains elusive. Because of this, our understanding of the sequence of events leading to global glacial conditions remains incomplete. Here we present multi-proxy evidence showing that northward shifts in Antarctic iceberg melt in the Indian–Atlantic Southern Ocean (0–50°E) systematically preceded deep-water mass reorganizations by 1-2 thousand years during Pleistocene-era glaciations. With the aid of iceberg-trajectory model experiments, we demonstrate that such a shift in iceberg trajectories during glacial periods can result in a considerable redistribution of freshwater in the Southern Ocean. This, in concert with increased sea-ice cover, may have enabled positive buoyancy anomalies to effectively escape into the ‘upper’ Atlantic overturning circulation limb, providing a teleconnection between surface Southern Ocean conditions and the formation of NADW. Furthermore, we observe a distinct obliquity pacing of Antarctic iceberg melt both preceding and following the Mid-Pleistocene Transition, become obscured during this interval. With new and existing data we investigate the evolution of orbital forcing at the Agulhas Plateau, considering the implications for ‘Southern Escape’ of freshwater as a key feedback in the transition to the ‘100-kyr world’.

Published
2021
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17. Antarctic icebergs reorganize ocean circulation during Pleistocene glacials

Author

Stratigraphy and paleontology, Stratigraphy & paleontology, Starr, Aidan, Hall, Ian R., Barker, Stephen, Rackow, Thomas, Zhang, Xu, Hemming, Sidney R., van der Lubbe, H. J.L., Knorr, Gregor, Berke, Melissa A., Bigg, Grant R., Cartagena-Sierra, Alejandra, Jiménez-Espejo, Francisco J., Gong, Xun, Gruetzner, Jens, Lathika, Nambiyathodi, LeVay, Leah J., Robinson, Rebecca S., Ziegler, Martin, Expedition 361 Science Party, Stratigraphy and paleontology, Stratigraphy & paleontology, Starr, Aidan, Hall, Ian R., Barker, Stephen, Rackow, Thomas, Zhang, Xu, Hemming, Sidney R., van der Lubbe, H. J.L., Knorr, Gregor, Berke, Melissa A., Bigg, Grant R., Cartagena-Sierra, Alejandra, Jiménez-Espejo, Francisco J., Gong, Xun, Gruetzner, Jens, Lathika, Nambiyathodi, LeVay, Leah J., Robinson, Rebecca S., Ziegler, Martin, and Expedition 361 Science Party

Published
2021

18. The interglacial-glacial sequence of events at the Agulhas Plateau: Antarctic icebergs lead ocean circulation into ice ages and across the Mid-Pleistocene Transition

Author

Starr, Aidan, Hall, Ian R., Barker, Stephen, Hemming, Sidney R., Rackow, Thomas, Zhang, Xu, van der Lubbe, J.J.L., Knorr, Gregor, Berke, Melissa A., Bigg, Grant R., Cartagena-Sierra, Alejandra, Jimenez-Espejo, Francisco J., Gong, Xun, Gruetzner, Jens, Lathika, Nambiyathodi, LeVay, Leah J., Ziegler, Martin, Starr, Aidan, Hall, Ian R., Barker, Stephen, Hemming, Sidney R., Rackow, Thomas, Zhang, Xu, van der Lubbe, J.J.L., Knorr, Gregor, Berke, Melissa A., Bigg, Grant R., Cartagena-Sierra, Alejandra, Jimenez-Espejo, Francisco J., Gong, Xun, Gruetzner, Jens, Lathika, Nambiyathodi, LeVay, Leah J., and Ziegler, Martin

Abstract

Palaeoceanographic evidence suggests that glacial periods of the Mid to Late Pleistocene were characterized by markedly different global ocean circulation patterns to modern; in the Atlantic basin, deep waters of Southern Ocean origin increased in volume while above them the core of the North Atlantic Deep Water (NADW) shoaled. Whilst proxy records and modelling efforts continue to clarify this picture, an evidence alluding to the origin of this phenomenon remains elusive. Because of this, our understanding of the sequence of events leading to global glacial conditions remains incomplete. Here we present multi-proxy evidence showing that northward shifts in Antarctic iceberg melt in the Indian–Atlantic Southern Ocean (0–50°E) systematically preceded deep-water mass reorganizations by 1-2 thousand years during Pleistocene-era glaciations. With the aid of iceberg-trajectory model experiments, we demonstrate that such a shift in iceberg trajectories during glacial periods can result in a considerable redistribution of freshwater in the Southern Ocean. This, in concert with increased sea-ice cover, may have enabled positive buoyancy anomalies to effectively escape into the ‘upper’ Atlantic overturning circulation limb, providing a teleconnection between surface Southern Ocean conditions and the formation of NADW. Furthermore, we observe a distinct obliquity pacing of Antarctic iceberg melt both preceding and following the Mid-Pleistocene Transition, become obscured during this interval. With new and existing data we investigate the evolution of orbital forcing at the Agulhas Plateau, considering the implications for ‘Southern Escape’ of freshwater as a key feedback in the transition to the ‘100-kyr world’.

Published
2021

19. Latitudinal Migrations of the Subtropical Front at the Agulhas Plateau Through the Mid‐Pleistocene Transition

Author

Cartagena‐Sierra, Alejandra, Berke, Melissa A., Robinson, Rebecca S., Marcks, Basia, Castañeda, Isla S., Starr, Aidan, Hall, Ian R., Hemming, Sidney R., LeVay, Leah J., Expedition 361 Scientific Party (incl. Jens Gruetzner), t., Cartagena‐Sierra, Alejandra, Berke, Melissa A., Robinson, Rebecca S., Marcks, Basia, Castañeda, Isla S., Starr, Aidan, Hall, Ian R., Hemming, Sidney R., LeVay, Leah J., and Expedition 361 Scientific Party (incl. Jens Gruetzner), t.

Abstract

The meridional variability of the Subtropical Front (STF) in the Southern Hemisphere, linked to expansions or contractions of the Southern Ocean, may have played an important role in global ocean circulation by moderating the magnitude of water exchange at the Indian-Atlantic Ocean Gateway, so called Agulhas Leakage. Here we present new biomarker records of upper water column temperature ( and ) and primary productivity (chlorins and alkenones) from marine sediments at IODP Site U1475 on the Agulhas Plateau, near the STF and within the Agulhas retroflection pathway. We use these multiproxy time-series records from 1.4 to 0.3 Ma to examine implied changes in the upper oceanographic conditions at the mid-Pleistocene transition (MPT, ca. 1.2?0.8 Ma). Our reconstructions, combined with prior evidence of migrations of the STF over the last 350 ka, suggest that in the Southwestern Indian Ocean the STF may have been further south from the Agulhas Plateau during the mid-Pleistocene Interim State (MPIS, MIS 23?12) and reached its northernmost position during MIS 34?24 and MIS 10. Comparison to a Globorotalia menardii-derived Agulhas Leakage reconstruction from the Cape Basin suggests that only the most extreme northward migrations of the STF are associated with reduced Agulhas Leakage. During the MPIS, STF migrations do not appear to control Agulhas Leakage variability, we suggest previously modeled shifting westerly winds may be responsible for the patterns observed. A detachment between STF migrations and Agulhas Leakage, in addition to invoking shifting westerly winds may also help explain changes in CO2 ventilation seen during the MPIS.

Published
2021

20. Strong glacial-interglacial variability in upper ocean hydrodynamics, biogeochemistry, and productivity in the southern Indian Ocean

Author

Ministerio de Ciencia e Innovación (España), European Commission, German Research Foundation, Ministerio de Ciencia, Innovación y Universidades (España), Tangunan, Deborah, Berke, Melissa A., Cartagena Sierra, Alejandra, Flores, José Abel, Gruetzner, Jens, Jiménez Espejo, Francisco J., LeVay, Leah J., Baumann, Karl-Heinz, Romero, Óscar, Saavedra-Pellitero, Mariem, Coenen, Jason J., Starr, Aidan, Hemming, Sidney R., Hall, Ian R., Ministerio de Ciencia e Innovación (España), European Commission, German Research Foundation, Ministerio de Ciencia, Innovación y Universidades (España), Tangunan, Deborah, Berke, Melissa A., Cartagena Sierra, Alejandra, Flores, José Abel, Gruetzner, Jens, Jiménez Espejo, Francisco J., LeVay, Leah J., Baumann, Karl-Heinz, Romero, Óscar, Saavedra-Pellitero, Mariem, Coenen, Jason J., Starr, Aidan, Hemming, Sidney R., and Hall, Ian R.

Abstract

In the southern Indian Ocean, the position of the subtropical front - the boundary between colder, fresher waters to the south and warmer, saltier waters to the north - has a strong influence on the upper ocean hydrodynamics and biogeochemistry. Here we analyse a sedimentary record from the Agulhas Plateau, located close to the modern position of the subtropical front and use alkenones and coccolith assemblages to reconstruct oceanographic conditions over the past 300,000 years. We identify a strong glacial-interglacial variability in sea surface temperature and productivity associated with subtropical front migration over the Agulhas Plateau, as well as shorter-term high frequency variability aligned with variations in high latitude insolation. Alkenone and coccolith abundances, in combination with diatom and organic carbon records indicate high glacial export productivity. We conclude that the biological pump was more efficient and strengthened during glacial periods, which could partly account for the reported reduction in atmospheric carbon dioxide concentrations. Migration of the Subtropical Front during glacial and interglacial periods resulted in variability in the strength of the biological pump in the Southern Ocean sector of the Indian Ocean, according to sedimentary records from the Agulhas Plateau.

Published
2021

21. Antarctic icebergs reorganize ocean circulation during Pleistocene glacials

Author

Ministerio de Ciencia e Innovación (España), Natural Environment Research Council (UK), National Key Research and Development Program (China), Helmholtz Association, European Commission, Starr, Aidan, Hall, Ian R., Barker, Stephen, Rackow, Thomas, Zhang, Xu, Hemming, Sidney R., Van Der Lubber, H. J. L., Knorr, Gregor, Berke, Melissa A., Bigg, Grant R., Cartagena Sierra, Alejandra, Jiménez Espejo, Francisco J., Gong, Xun, Gruetzner, Jens, Lathika, Nambiyathodi, LeVay, Leah J., Robinson, Rebecca S., Ziegler, Martin, Ministerio de Ciencia e Innovación (España), Natural Environment Research Council (UK), National Key Research and Development Program (China), Helmholtz Association, European Commission, Starr, Aidan, Hall, Ian R., Barker, Stephen, Rackow, Thomas, Zhang, Xu, Hemming, Sidney R., Van Der Lubber, H. J. L., Knorr, Gregor, Berke, Melissa A., Bigg, Grant R., Cartagena Sierra, Alejandra, Jiménez Espejo, Francisco J., Gong, Xun, Gruetzner, Jens, Lathika, Nambiyathodi, LeVay, Leah J., Robinson, Rebecca S., and Ziegler, Martin

Abstract

The dominant feature of large-scale mass transfer in the modern ocean is the Atlantic meridional overturning circulation (AMOC). The geometry and vigour of this circulation influences global climate on various timescales. Palaeoceanographic evidence suggests that during glacial periods of the past 1.5 million years the AMOC had markedly different features from today; in the Atlantic basin, deep waters of Southern Ocean origin increased in volume while above them the core of the North Atlantic Deep Water (NADW) shoaled. An absence of evidence on the origin of this phenomenon means that the sequence of events leading to global glacial conditions remains unclear. Here we present multi-proxy evidence showing that northward shifts in Antarctic iceberg melt in the Indian–Atlantic Southern Ocean (0–50° E) systematically preceded deep-water mass reorganizations by one to two thousand years during Pleistocene-era glaciations. With the aid of iceberg-trajectory model experiments, we demonstrate that such a shift in iceberg trajectories during glacial periods can result in a considerable redistribution of freshwater in the Southern Ocean. We suggest that this, in concert with increased sea-ice cover, enabled positive buoyancy anomalies to ‘escape’ into the upper limb of the AMOC, providing a teleconnection between surface Southern Ocean conditions and the formation of NADW. The magnitude and pacing of this mechanism evolved substantially across the mid-Pleistocene transition, and the coeval increase in magnitude of the ‘southern escape’ and deep circulation perturbations implicate this mechanism as a key feedback in the transition to the ‘100-kyr world’, in which glacial–interglacial cycles occur at roughly 100,000-year periods.

Published
2021

22. Latitudinal Migrations of the Subtropical Front at the Agulhas Plateau Through the Mid-Pleistocene Transition

Author

Cartagena-Sierra, Alejandra, Berke, Melissa A., Robinson, Rebecca S., Marcks, Basia, Castañeda, Isla S., Starr, Aidan, Hall, Ian R., Hemming, Sidney R., LeVay, Leah J., Cartagena-Sierra, Alejandra, Berke, Melissa A., Robinson, Rebecca S., Marcks, Basia, Castañeda, Isla S., Starr, Aidan, Hall, Ian R., Hemming, Sidney R., and LeVay, Leah J.

Abstract

The meridional variability of the Subtropical Front (STF) in the Southern Hemisphere, linked to expansions or contractions of the Southern Ocean, may have played an important role in global ocean circulation by moderating the magnitude of water exchange at the Indian-Atlantic Ocean Gateway, so called Agulhas Leakage. Here we present new biomarker records of upper water column temperature ((Formula presented.) and (Formula presented.)) and primary productivity (chlorins and alkenones) from marine sediments at IODP Site U1475 on the Agulhas Plateau, near the STF and within the Agulhas retroflection pathway. We use these multiproxy time-series records from 1.4 to 0.3 Ma to examine implied changes in the upper oceanographic conditions at the mid-Pleistocene transition (MPT, ca. 1.2–0.8 Ma). Our reconstructions, combined with prior evidence of migrations of the STF over the last 350 ka, suggest that in the Southwestern Indian Ocean the STF may have been further south from the Agulhas Plateau during the mid-Pleistocene Interim State (MPIS, MIS 23–12) and reached its northernmost position during MIS 34–24 and MIS 10. Comparison to a Globorotalia menardii-derived Agulhas Leakage reconstruction from the Cape Basin suggests that only the most extreme northward migrations of the STF are associated with reduced Agulhas Leakage. During the MPIS, STF migrations do not appear to control Agulhas Leakage variability, we suggest previously modeled shifting westerly winds may be responsible for the patterns observed. A detachment between STF migrations and Agulhas Leakage, in addition to invoking shifting westerly winds may also help explain changes in CO2 ventilation seen during the MPIS.

Published
2021

23. A plio-pleistocene (C. 0–4 ma) cyclostratigraphy for iodp site u1478 (mozambique channel, sw indian ocean): Exploring an offshore record of paleoclimate and ecosystem variability in se africa

Author

Koutsodendris, Andreas, Nakajima, Kai, Kaboth-Bahr, Stefanie, Berke, Melissa A., Franzese, Allison M., Hall, Ian R., Hemming, Sidney R., Just, Janna, Levay, Leah J., Pross, Jörg, Robinson, Rebecca, Barker, S., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C. D., Coenen, J. J., Crespin, J. G., Gruetzner, J., Han, X., Hines, S. K.V., Espejo, F. J. Jimenez, Kubota, K., Lathika, N., Norris, R. D., Dos Santos, T. Pereira, Rolinson, J. M., Simon, M. H., Tangunan, D., van der Lubbe, J. J.L., Yamane, M., Zhang, H., Koutsodendris, Andreas, Nakajima, Kai, Kaboth-Bahr, Stefanie, Berke, Melissa A., Franzese, Allison M., Hall, Ian R., Hemming, Sidney R., Just, Janna, Levay, Leah J., Pross, Jörg, Robinson, Rebecca, Barker, S., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C. D., Coenen, J. J., Crespin, J. G., Gruetzner, J., Han, X., Hines, S. K.V., Espejo, F. J. Jimenez, Kubota, K., Lathika, N., Norris, R. D., Dos Santos, T. Pereira, Rolinson, J. M., Simon, M. H., Tangunan, D., van der Lubbe, J. J.L., Yamane, M., and Zhang, H.

Abstract

The paleoclimate and ecosystem variability in Africa during the Plio/Pleistocene has received considerable attention due to its potential links to hominid evolution. However, the reconstruction of this variability hinges critically upon highly temporally resolved proxy data from continuous, well-dated sediment archives. In light of these requirements we use a new XRF core-scanning record from International Ocean Discovery Program (IODP) Site U1478 off the Limpopo River mouth (Mozambique Channel, SW Indian Ocean) spanning the past c. 4 Ma to identify the climate variability in SE Africa. Our results show that the elemental distribution in the Site U1478 cores is mainly controlled by the rate of terrigenous input and – to a lesser extent – by bottom-current transport and post-depositional processes such as propagation of paleoredox boundaries and diagenesis across some intervals. The log(Ti/Ca) ratio, which is used as a tracer of terrigenous sediment input, shows quasi-cyclical variability across the entire record that closely matches the periods of orbital parameters. However, the cyclical behaviour of the log(Ti/Ca) signal varies through time, with the uppermost 106 m of the sequence (0–1.07 Ma) displaying a mix of precession and obliquity signals, the intervals 106–223 m (1.07–2.80 Ma) and 240–257 m (3.68–4.05 Ma) being dominated by precession, and the interval 223–240 m (2.80–3.68 Ma) being controlled by eccentricity. To refine the available chronology for Site U1478, which is based on shipboard biostratigraphic and paleomagnetic data, we have tuned the log(Ti/Ca) record to the LR04 benthic oxygen isotope record, summer insolation at 25° S, and orbital eccentricity depending on the dominant cyclicities in the XRF dataset across individual time intervals. The resulting chronology enables us to evaluate the XRF data as well as the previously available shipboard sedimentological and geochemical datasets within a regional and global climatic context. This allows the c

Published
2021

24. The interglacial-glacial sequence of events at the Agulhas Plateau: Antarctic icebergs lead ocean circulation into ice ages and across the Mid-Pleistocene Transition

Author

Starr, Aidan, primary, Hall, Ian, additional, Barker, Stephen, additional, Hemming, Sidney, additional, Rackow, Thomas, additional, Zhang, Xu, additional, van der Lubbe, H.J.L, additional, Knorr, Gregor, additional, Berke, Melissa, additional, Bigg, Grant, additional, Cartagena-Sierra, Alejandra, additional, Jimenez-Espejo, Francisco, additional, Gong, Xun, additional, Gruetzner, Jens, additional, Lathka, Nambiyathodi, additional, LeVay, Leah, additional, and Ziegler, Martin, additional

Published
2021
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25. Surface and deep-water variability on the southern Agulhas Plateau: Interhemispheric links over the past 2 Ma

Author

Hall, Ian R., Starr, Aidan, Hemming, Sidney R., Barker, Stephen, Van Der Lubber, Jeroen, Cartagena Sierra, Alejandra, Berke, Melissa A., Gruetzner, Jens, Jiménez Espejo, Francisco J., LeVay, Leah J., Lathika, Nambiyathodi, and Robinson, Rebecca S.

Abstract

AGU's Fall Meeting 2019, in San Francisco (EE.UU.) 9–13 December 2019, The Southern Ocean is involved in setting the state of global climate through its role in redistributing heat and salt through the world ocean and its control on atmospheric CO2. Utilising sediment core sites on the southern Agulhas Plateau (AP) in the southwest Indian Ocean, we present new records of ice-rafted debris mass accumulation rate (IRDMAR), intermediate and benthic oxygen and carbon isotope, sortable silt mean grain size and bulk sediment chemistry (XRF) spanning the past 2 Ma. The AP is situated at the southern extent of the Indian-Atlantic Ocean Gateway (I-AOG); the upper water column is dominated by Indian Ocean waters not leaked into the South Atlantic and instead flowing eastward as the Agulhas Return Current. South of the AP, the relatively cold and fresh waters of the Sub-Antarctic Zone (SAZ) meet their northern limit and steep meridional property gradients occur. The AP region is therefore highly sensitive to variations in both the Sub-Antarctic Zone (SAZ) to the south and the Agulhas Current System to the north. IODP Site U1475 (41°25.61¿S; 25°15.64¿E, 2669 m water depth), was recovered from a contourite drift deposit on the southern AP, situated close to the modern-day subtropical front. Together with complementary data from sediment core MD02-2588 from the same location, our results indicate that during glacial periods there was a persistent influence of a well-ventilated water mass within the I-AOG with a carbon isotope signature similar to present-day Northern Component Water (NCW). The records of chemical ventilation and near-bottom flow vigour closely reflect changes in the advection of NCW and meridional variability in the location of the Antarctic Circumpolar Current and its associated fronts, as recorded by IRDMAR. We suggest that equatorward expansions of the circum-Antarctic frontal system, occurring relatively early in the glacial sequence, are central in triggering this glacial overturning circulation, hence modulating global climate. On orbital timescales, the SAZ represents a window through which external forcing may be translated into the global climate system; likely relevant for the enigmatic Mid-Pleistocene Transition.

Published
2019

26. A New Seismic Stratigraphy in the Indian-Atlantic Ocean Gateway Resembles Major Paleo-Oceanographic Changes of the Last 7 Ma

Author

Gruetzner, Jens, Jimenez Espejo, Francisco J., Lathika, Nambiyathodi, Uenzelmann-Neben, Gabriele, Hall, Ian R., Hemming, Sidney R., LeVay, Leah J., Barker, S., Berke, M. A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C. D., Coenen, J. J., Crespin, J. G., Franzese, A. M., Han, X., Hines, S. K. V., Just, J., Koutsodendris, A., Kubota, K., Norris, R. D., Santos, T. P., Robinson, R., Rolinson, J. M., Simon, M. H., Tangunan, D., van der Lubbe, H. J. L., Yamane, M., Zhang, H., Gruetzner, Jens, Jimenez Espejo, Francisco J., Lathika, Nambiyathodi, Uenzelmann-Neben, Gabriele, Hall, Ian R., Hemming, Sidney R., LeVay, Leah J., Barker, S., Berke, M. A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C. D., Coenen, J. J., Crespin, J. G., Franzese, A. M., Han, X., Hines, S. K. V., Just, J., Koutsodendris, A., Kubota, K., Norris, R. D., Santos, T. P., Robinson, R., Rolinson, J. M., Simon, M. H., Tangunan, D., van der Lubbe, H. J. L., Yamane, M., and Zhang, H.

Abstract

The exchange of water masses between the Indian Ocean and the Atlantic constitutes an integral interocean link in the global thermohaline circulation. Long-term changes in deep water flow have been studied using seismic reflection profiles but the seismic stratigraphy was poorly constrained and not resolved for the time period from the late Miocene onward. Here we present results from International Ocean Discovery Program Site U1475 (Agulhas Plateau) located over a sediment drift proximal to the entrance of North Atlantic Deep Water into the Southern Ocean and South Indian Ocean. Site U1475 comprises a complete carbonate-rich stratigraphic section of the last similar to 7 Ma that provides an archive of climate-induced variations in ocean circulation. Six marker reflectors occurring in the upper 300 m of the drift are identified here for the first time. The formation of these reflectors is mainly due to density changes that are mostly caused by changes in biogenic versus terrigenous sediment deposition. Synthetic seismograms allow age assignments for the horizons based on biostratigraphy and magnetostratigraphy. Prominent reflectors are related to late Pleistocene glacial/interglacial variability, the middle and early Pleistocene transitions, and the onset of the northern hemisphere glaciation. A peculiar early Pliocene interval (similar to 5.3-4.0 Ma) bounded by two reflectors is characterized by fourfold elevated sedimentation rates (> 10 cm/kyr) and the occurrence of sediment waves. We argue that this enhanced sediment transport to the Agulhas Plateau was caused by a reorganization of the bottom current circulation pattern due to maximized inflow of North Atlantic Deep Water.

Published
2019

28. Expedition 361 summary

Author

Richard D Norris, D. Tangunan, Stephen Barker, A. Cartagena-Sierra, J.G. Crespin, Sidney R. Hemming, F.J. Jimenez Espejo, Rebecca S. Robinson, H. Zhang, Leah J. LeVay, Christopher D. Charles, Nambiyathodi Lathika, S.K.V. Hines, Berke, Masako Yamane, Andreas Koutsodendris, A.M. Franzese, Jens Gruetzner, J.J. Coenen, L. Brentegani, M.H. Simon, Ian Hall, X. Han, T. Periera dos Santos, Janna Just, Kaoru Kubota, Thibaut Caley, J.J.L. van der Lubbe, and J.M. Rolinson

Subjects
geography, Plateau, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Pleistocene, Global warming, Temperature salinity diagrams, Last Glacial Maximum, International Ocean Discovery Program, 010502 geochemistry & geophysics, 01 natural sciences, Boundary current, Oceanography, Extratropical cyclone, Geology, 0105 earth and related environmental sciences
Abstract

International Ocean Discovery Program Expedition 361 drilled six sites on the southeast African margin (southwest Indian Ocean) and in the Indian-Atlantic Ocean gateway, from 30 January to 31 March 2016. In total, 5175 m of core was recovered, with an average recovery of 102%, during 29.7 days of on-site operations. The sites, situated in the Mozambique Channel at locations directly influenced by discharge from the Zambezi and Limpopo River catchments, the Natal Valley, the Agulhas Plateau, and Cape Basin, were targeted to reconstruct the history of the greater Agulhas Current system over the past ~5 My. The Agulhas Current is the strongest western boundary current in the Southern Hemisphere, transporting some 70 Sv of warm, saline surface water from the tropical Indian Ocean along the East African margin to the tip of Africa. Exchanges of heat and moisture with the atmosphere influence southern African climates, including individual weather systems such as extratropical cyclone formation in the region and rainfall patterns. Recent ocean model and paleoceanographic data further point at a potential role of the Agulhas Current in controlling the strength and mode of the Atlantic Meridional Overturning Circulation (AMOC) during the Late Pleistocene. Spillage of saline Agulhas water into the South Atlantic stimulates buoyancy anomalies that may influence basin-wide AMOC, with implications for convective activity in the North Atlantic and global climate change. The main objectives of the expedition were to establish the role of the Agulhas Current in climatic changes during the Pliocene–Pleistocene, specifically to document the dynamics of the Indian-Atlantic Ocean gateway circulation during this time, to examine the connection of the Agulhas leakage and AMOC, and to address the influence of the Agulhas Current on African terrestrial climates and coincidences with human evolution. Additionally, the expedition set out to fulfill the needs of Ancillary Project Letter number 845, consisting of high-resolution interstitial water sampling to help constrain the temperature and salinity profiles of the ocean during the Last Glacial Maximum. The expedition made major strides toward fulfilling each of these objectives. The recovered sequences allowed generation of complete spliced stratigraphic sections that range from 0 to between ~0.13 and 7 Ma. This sediment will provide decadal- to millennial-scale climatic records that will allow answering the paleoceanographic and paleoclimatic questions set out in the drilling proposal.

Published
2017
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29. Site U1476

Author

I.R. Hall, S.R. Hemming, L.J. LeVay, S. Barker, M.A. Berke, L. Brentegani, T. Caley, A. Cartagena-Sierra, C.D. Charles, J.J. Coenen, J.G. Crespin, A.M. Franzese, J. Gruetzner, X. Han, S.K.V. Hines, F.J. Jimenez Espejo, J. Just, A. Koutsodendris, K. Kubota, N. Lathika, R.D. Norris, T. Periera dos Santos, R. Robinson, J.M. Rolinson, M.H. Simon, D. Tangunan, J.J.L. van der Lubbe, M. Yamane, and H. Zhang

Published
2017
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30. Expedition 361 methods

Author

Janna Just, F.J. Jimenez Espejo, Stephen Barker, J.J. Coenen, J.G. Crespin, L. Brentegani, Sidney R. Hemming, J.J.L. van der Lubbe, Thibaut Caley, Masako Yamane, X. Han, D. Tangunan, Jens Gruetzner, Richard D Norris, T. Periera dos Santos, Ian Hall, Christopher D. Charles, J.M. Rolinson, Andreas Koutsodendris, M.H. Simon, Nambiyathodi Lathika, Leah J. LeVay, A.M. Franzese, A. Cartagena-Sierra, Rebecca S. Robinson, S.K.V. Hines, Melissa A. Berke, Kaoru Kubota, and H. Zhang

Subjects
010504 meteorology & atmospheric sciences, 010502 geochemistry & geophysics, 01 natural sciences, Geology, 0105 earth and related environmental sciences
Published
2017
Full Text
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31. Proceedings of the International Ocean Discovery Program; South African climates (Agulhas LGM density profile); Expedition 361 of the riserless drilling platform, Port Louis, Mauritius, to Cape Town, South Africa; Sites U1474-U1479, 30 January-31 March 2016

Author

Hall, Ian R., Hemming, Sidney R., Levay, Leah J., Barker, Stephen R., Berke, Melissa A., Luna Brentegani, Thibaut Caley, Alejandra Cartagena-Sierra, Charles, Christopher D., Coenen, Jason J., Crespin, Julien G., Franzese, Allison M., Jens Gruetzner, Han Xibin, Hines, Sophia K. V., Jimenez Espejo, Francisco J., Janna Just, Andreas Koutsodendris, Kaoru Kubota, Nambiyathodi Lathika, Norris, Richard D., Thiago Pereira dos Santos, Rebecca Robinson, Rolison, John M., Simon, Margit H., Deborah Tangunan, Jeroen van der Lubbe, Masako Yamane, Zhang Hucai, and Geology and Geochemistry

Subjects
Agulhas Current, Algae, Atlantic Ocean, Biostratigraphy, Cenozoic, Cores, Correlation, Diatoms, Expedition 361, Foraminifera, Geochemistry, Hydrochemistry, Indian Ocean, International Ocean Discovery Program, Invertebrata, Lithostratigraphy, Magnetostratigraphy, Marine sediments, Microfossils, Mozambique Channel, Nannofossils, Neogene, Paleo-oceanography, Paleoclimatology, Physical properties, Plantae, Pore water, Protista, Quaternary, Sediments, South Atlantic, Southeast Atlantic, Tertiary, West Indian Ocean, 12 Stratigraphy, Historical Geology and Paleoecology
Published
2017

32. Site U1478

Author

Hall, I.R., Hemming, S.R., LeVay, L.J., Expedition 361 Scientists, t, Barker, S., Berke, M.A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C.D., Coenen, J.J., Crespin, J.G., Franzese, A.M., Gruetzner, J., Han, X., Hines, S.K.V., Jimenez Espejo, F.J., Just, J., Koutsodendris, A., Kubota, K., Lathika, N., Norris, R.D., Periera dos Santos, T., Robinson, R., Rolinson, J.M., Simon, M.H., Tangunan, D., van der Lubbe, J.J.L., Yamane, M., Zhang, H., Hall, I.R., Hemming, S.R., LeVay, L.J., Expedition 361 Scientists, t, Barker, S., Berke, M.A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C.D., Coenen, J.J., Crespin, J.G., Franzese, A.M., Gruetzner, J., Han, X., Hines, S.K.V., Jimenez Espejo, F.J., Just, J., Koutsodendris, A., Kubota, K., Lathika, N., Norris, R.D., Periera dos Santos, T., Robinson, R., Rolinson, J.M., Simon, M.H., Tangunan, D., van der Lubbe, J.J.L., Yamane, M., and Zhang, H.

Published
2017

33. Site U1475

Author

Hall, I. R., Hemming, S.R., LeVay, L.J., Expedition 361 Scientists, the, Hall, I.R., Barker, S., Berke, M.A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C.D., Coenen, J.J., Crespin, J.G., Franzese, A.M., Gruetzner, J., Han, X., Hines, S.K.V., Jimenez Espejo, F.J., Just, J., Koutsodendris, A., Kubota, K., Lathika, N., Norris, R.D., Periera dos Santos, T., Robinson, R., Rolinson, J.M., Simon, M.H., Tangunan, D., van der Lubbe, J.J.L., Yamane, M., Zhang, H., Hall, I. R., Hemming, S.R., LeVay, L.J., Expedition 361 Scientists, the, Hall, I.R., Barker, S., Berke, M.A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C.D., Coenen, J.J., Crespin, J.G., Franzese, A.M., Gruetzner, J., Han, X., Hines, S.K.V., Jimenez Espejo, F.J., Just, J., Koutsodendris, A., Kubota, K., Lathika, N., Norris, R.D., Periera dos Santos, T., Robinson, R., Rolinson, J.M., Simon, M.H., Tangunan, D., van der Lubbe, J.J.L., Yamane, M., and Zhang, H.

Published
2017

34. Expedition 361 summary

Author

Hall, I.R., Hemming, S.R., LeVay, L.J., Expedition 361 Scientists, the, Barker, S., Berke, M.A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C.D., Coenen, J.J., Crespin, J.G., Franzese, A.M., Gruetzner, J., Han, X., Hines, S.K.V., Jimenez Espejo, F.J., Just, J., Koutsodendris, A., Kubota, K., Lathika, N., Norris, R.D., Periera dos Santos, T., Robinson, R., Rolinson, J.M., Simon, M.H., Tangunan, D., van der Lubbe, J.J.L., Yamane, M., Zhang, H., Hall, I.R., Hemming, S.R., LeVay, L.J., Expedition 361 Scientists, the, Barker, S., Berke, M.A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C.D., Coenen, J.J., Crespin, J.G., Franzese, A.M., Gruetzner, J., Han, X., Hines, S.K.V., Jimenez Espejo, F.J., Just, J., Koutsodendris, A., Kubota, K., Lathika, N., Norris, R.D., Periera dos Santos, T., Robinson, R., Rolinson, J.M., Simon, M.H., Tangunan, D., van der Lubbe, J.J.L., Yamane, M., and Zhang, H.

Abstract

International Ocean Discovery Program Expedition 361 drilled six sites on the southeast African margin (southwest Indian Ocean) and in the Indian-Atlantic Ocean gateway, from 30 January to 31 March 2016. In total, 5175 m of core was recovered, with an average recovery of 102%, during 29.7 days of on-site operations. The sites, situated in the Mozambique Channel at locations directly influenced by discharge from the Zambezi and Limpopo River catchments, the Natal Valley, the Agulhas Plateau, and Cape Basin, were targeted to reconstruct the history of the greater Agulhas Current system over the past ~5 My. The Agulhas Current is the strongest western boundary current in the Southern Hemisphere, transporting some 70 Sv of warm, saline surface water from the tropical Indian Ocean along the East African margin to the tip of Africa. Exchanges of heat and moisture with the atmosphere influence southern African climates, including individual weather systems such as extratropical cyclone formation in the region and rainfall patterns. Recent ocean model and paleoceanographic data further point at a potential role of the Agulhas Current in controlling the strength and mode of the Atlantic Meridional Overturning Circulation (AMOC) during the Late Pleistocene. Spillage of saline Agulhas water into the South Atlantic stimulates buoyancy anomalies that may influence basin-wide AMOC, with implications for convective activity in the North Atlantic and global climate change. The main objectives of the expedition were to establish the role of the Agulhas Current in climatic changes during the Pliocene–Pleistocene, specifically to document the dynamics of the Indian-Atlantic Ocean gateway circulation during this time, to examine the connection of the Agulhas leakage and AMOC, and to address the influence of the Agulhas Current on African terrestrial climates and coincidences with human evolution. Additionally, the expedition set out to fulfill the needs of Ancillary Project Letter numb

Published
2017

35. Expedition 361 methods

Author

Hall, I. R., Hemming, S.R., LeVay, L.J., Expedition 361 Scientists, the, Hall, I.R., Barker, S., Berke, M.A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C.D., Coenen, J.J., Crespin, J.G., Franzese, A.M., Gruetzner, J., Han, X., Hines, S.K.V., Jimenez Espejo, F.J., Just, J., Koutsodendris, A., Kubota, K., Lathika, N., Norris, R.D., Periera dos Santos, T., Robinson, R., Rolinson, J.M., Simon, M.H., Tangunan, D., van der Lubbe, J.J.L., Yamane, M., Zhang, H., Hall, I. R., Hemming, S.R., LeVay, L.J., Expedition 361 Scientists, the, Hall, I.R., Barker, S., Berke, M.A., Brentegani, L., Caley, T., Cartagena-Sierra, A., Charles, C.D., Coenen, J.J., Crespin, J.G., Franzese, A.M., Gruetzner, J., Han, X., Hines, S.K.V., Jimenez Espejo, F.J., Just, J., Koutsodendris, A., Kubota, K., Lathika, N., Norris, R.D., Periera dos Santos, T., Robinson, R., Rolinson, J.M., Simon, M.H., Tangunan, D., van der Lubbe, J.J.L., Yamane, M., and Zhang, H.

Published
2017

36. International Ocean Discovery Program; Expedition 361 preliminary report; South African climates (Agulhas LGM density profile); 30 January-31 March 2016

Author

Hall, Ian R., Hemming, Sidney R., Levay, Leah J., Barker, Stephen R., Berke, Melissa A., Luna Brentegani, Thibaut Caley, Alejandra Cartagena-Sierra, Charles, Christopher D., Coenen, Jason J., Crespin, Julien G., Franzese, Allison M., Jens Gruetzner, Han Xibin, Hins, Sophia K. V., Jimenez Espejo, Francisco J., Janna Just, Andreas Koutsodendris, Kaoru Kubota, Nambiyathodi Lathika, Norris, Richard D., Thiago Pereira dos Santos, Rebecca Robinson, Rolison, John M., Simon, Margit H., Deborah Tangunan, Jeroen van der Lubbe, Masako Yamane, Zhang Hucai, and Geology and Geochemistry

Subjects
Africa, Agulhas Current, Algae, Atlantic Meridional Overturning Circulation, Atlantic Ocean, Biostratigraphy, Cenozoic, Chemostratigraphy, Climate effects, Continental margin, Cores, Currents, Expedition 361, Foraminifera, IODP Site U1474, IODP Site U1475, IODP Site U1476, IODP Site U1477, IODP Site U1478, IODP Site U1479, Indian Ocean, International Ocean Discovery Program, Invertebrata, Last glacial maximum, Lithostratigraphy, Magnetostratigraphy, Marine sediments, Microfossils, Mozambique Channel, Nannofossils, Neogene, Ocean circulation, Ocean currents, Paleo-oceanography, Paleoclimatology, Paleomagnetism, Physical properties, Plantae, Pleistocene, Pliocene, Protista, Quaternary, Sediments, South Atlantic, Southeast Atlantic, Southern Africa, Tertiary, SDG 14 - Life Below Water, 12 Stratigraphy, Historical Geology and Paleoecology
Abstract

International Ocean Discovery Program (IODP) Expedition 361 drilled six sites on the southeast African margin and in the Indian-Atlantic ocean gateway, southwest Indian Ocean, from 30 January to 31 March 2016. In total, 5175 m of core was recovered, with an average recovery of 102%, during 29.7 days of on-site operations. The sites, situated in the Mozambique Channel at locations directly influenced by discharge from the Zambezi and Limpopo River catchments, the Natal Valley, the Agulhas Plateau, and Cape Basin, were targeted to reconstruct the history of the greater Agulhas Current system over the past ∼5 my. The Agulhas Current is the strongest western boundary current in the Southern Hemisphere, transporting some 70 Sv of warm, saline surface water from the tropical Indian Ocean along the East African margin to the tip of Africa. Exchanges of heat and moisture with the atmosphere influence southern African climates, including individual weather systems such as extratropical cyclone formation in the region and rainfall patterns. Recent ocean model and paleoceanographic data further point at a potential role of the Agulhas Current in controlling the strength and mode of the Atlantic Meridional Overturning Circulation (AMOC) during the Late Pleistocene. Spillage of saline Agulhas water into the South Atlantic stimulates buoyancy anomalies that act as control mechanisms on the basin-wide AMOC, with implications for convective activity in the North Atlantic and global climate change. The main objectives of the expedition were to establish the sensitivity of the Agulhas Current to climatic changes during the Pliocene-Pleistocene, to determine the dynamics of the Indian-Atlantic gateway circulation during this time, to examine the connection of the Agulhas leakage and AMOC, and to address the influence of the Agulhas Current on African terrestrial climates and coincidences with human evolution. Additionally, the expedition set out to fulfill the needs of the Ancillary Project Letter, consisting of high-resolution interstitial water samples that will constrain the temperature and salinity profiles of the ocean during the Last Glacial Maximum. The expedition made major strides toward fulfilling each of these objectives. The recovered sequences allowed generation of complete spliced stratigraphic sections that span from 0 to between ∼0.13 and 7 Ma. This sediment will provide decadal- to millennial-scale climatic records that will allow answering the paleoceanographic and paleoclimatic questions set out in the drilling proposal.

37. International Ocean Discovery Program; Expedition 361 preliminary report; South African climates (Agulhas LGM density profile); 30 January-31 March 2016

Author

Hall, Ian R., Hemming, Sidney R., LeVay, Leah J., Barker, Stephen R., Berke, Melissa A., Brentegani, Luna, Caley, Thibaut, Cartagena-Sierra, Alejandra, Charles, Christopher D., Coenen, Jason J., Crespin, Julien G., Franzese, Allison M., Gruetzner, Jens, Xibin, Han, Hins, Sophia K. V., Jimenez Espejo, Francisco J., Just, Janna, Koutsodendris, Andreas, Kubota, Kaoru, Lathika, Nambiyathodi, Norris, Richard D., Pereira dos Santos, Thiago, Robinson, Rebecca, Rolison, John M., Simon, Margit H., Tangunan, Deborah, van der Lubbe, Jeroen (H,) J. L., Yamane, Masako, and Hucai, Zhang

Subjects
Historical Geology and Paleoecology, Africa, Agulhas Current, Algae, Atlantic Meridional Overturning Circulation, Atlantic Ocean, Biostratigraphy, Cenozoic, Chemostratigraphy, Climate effects, Continental margin, Cores, Currents, Expedition 361, Foraminifera, IODP Site U1474, IODP Site U1475, IODP Site U1476, IODP Site U1477, IODP Site U1478, IODP Site U1479, Indian Ocean, International Ocean Discovery Program, Invertebrata, Last glacial maximum, Lithostratigraphy, Magnetostratigraphy, Marine sediments, Microfossils, Mozambique Channel, Nannofossils, Neogene, Ocean circulation, Ocean currents, Paleo-oceanography, Paleoclimatology, Paleomagnetism, Physical properties, Plantae, Pleistocene, Pliocene, Protista, Quaternary, Sediments, South Atlantic, Southeast Atlantic, Southern Africa, Tertiary, SDG 14 - Life Below Water, 12 Stratigraphy, Historical Geology and Paleoecology, 12 Stratigraphy
Abstract

International Ocean Discovery Program (IODP) Expedition 361 drilled six sites on the southeast African margin and in the Indian-Atlantic ocean gateway, southwest Indian Ocean, from 30 January to 31 March 2016. In total, 5175 m of core was recovered, with an average recovery of 102%, during 29.7 days of on-site operations. The sites, situated in the Mozambique Channel at locations directly influenced by discharge from the Zambezi and Limpopo River catchments, the Natal Valley, the Agulhas Plateau, and Cape Basin, were targeted to reconstruct the history of the greater Agulhas Current system over the past ∼5 my. The Agulhas Current is the strongest western boundary current in the Southern Hemisphere, transporting some 70 Sv of warm, saline surface water from the tropical Indian Ocean along the East African margin to the tip of Africa. Exchanges of heat and moisture with the atmosphere influence southern African climates, including individual weather systems such as extratropical cyclone formation in the region and rainfall patterns. Recent ocean model and paleoceanographic data further point at a potential role of the Agulhas Current in controlling the strength and mode of the Atlantic Meridional Overturning Circulation (AMOC) during the Late Pleistocene. Spillage of saline Agulhas water into the South Atlantic stimulates buoyancy anomalies that act as control mechanisms on the basin-wide AMOC, with implications for convective activity in the North Atlantic and global climate change. The main objectives of the expedition were to establish the sensitivity of the Agulhas Current to climatic changes during the Pliocene-Pleistocene, to determine the dynamics of the Indian-Atlantic gateway circulation during this time, to examine the connection of the Agulhas leakage and AMOC, and to address the influence of the Agulhas Current on African terrestrial climates and coincidences with human evolution. Additionally, the expedition set out to fulfill the needs of the Ancillary Project Letter, consisting of high-resolution interstitial water samples that will constrain the temperature and salinity profiles of the ocean during the Last Glacial Maximum. The expedition made major strides toward fulfilling each of these objectives. The recovered sequences allowed generation of complete spliced stratigraphic sections that span from 0 to between ∼0.13 and 7 Ma. This sediment will provide decadal- to millennial-scale climatic records that will allow answering the paleoceanographic and paleoclimatic questions set out in the drilling proposal.

Published
2016

38. Persistent influence of precession on northern ice sheet variability since the early Pleistocene.

Author

Barker S, Starr A, van der Lubbe J, Doughty A, Knorr G, Conn S, Lordsmith S, Owen L, Nederbragt A, Hemming S, Hall I, Levay L, Berke MA, Brentegani L, Caley T, Cartagena-Sierra A, Charles CD, Coenen JJ, Crespin JG, Franzese AM, Gruetzner J, Han X, Hines SKV, Jimenez Espejo FJ, Just J, Koutsodendris A, Kubota K, Lathika N, Norris RD, Periera Dos Santos T, Robinson R, Rolison JM, Simon MH, Tangunan D, Yamane M, and Zhang H

Abstract

Prior to ~1 million years ago (Ma), variations in global ice volume were dominated by changes in obliquity; however, the role of precession remains unresolved. Using a record of North Atlantic ice rafting spanning the past 1.7 million years, we find that the onset of ice rafting within a given glacial cycle (reflecting ice sheet expansion) consistently occurred during times of decreasing obliquity whereas mass ice wasting (ablation) events were consistently tied to minima in precession. Furthermore, our results suggest that the ubiquitous association between precession-driven mass wasting events and glacial termination is a distinct feature of the mid to late Pleistocene. Before then (increasing), obliquity alone was sufficient to end a glacial cycle, before losing its dominant grip on deglaciation with the southward extension of Northern Hemisphere ice sheets since ~1 Ma.

Published
2022
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39. Antarctic icebergs reorganize ocean circulation during Pleistocene glacials.

Author

Starr A, Hall IR, Barker S, Rackow T, Zhang X, Hemming SR, van der Lubbe HJL, Knorr G, Berke MA, Bigg GR, Cartagena-Sierra A, Jiménez-Espejo FJ, Gong X, Gruetzner J, Lathika N, LeVay LJ, Robinson RS, and Ziegler M

Abstract

The dominant feature of large-scale mass transfer in the modern ocean is the Atlantic meridional overturning circulation (AMOC). The geometry and vigour of this circulation influences global climate on various timescales. Palaeoceanographic evidence suggests that during glacial periods of the past 1.5 million years the AMOC had markedly different features from today 1 ; in the Atlantic basin, deep waters of Southern Ocean origin increased in volume while above them the core of the North Atlantic Deep Water (NADW) shoaled 2 . An absence of evidence on the origin of this phenomenon means that the sequence of events leading to global glacial conditions remains unclear. Here we present multi-proxy evidence showing that northward shifts in Antarctic iceberg melt in the Indian-Atlantic Southern Ocean (0-50° E) systematically preceded deep-water mass reorganizations by one to two thousand years during Pleistocene-era glaciations. With the aid of iceberg-trajectory model experiments, we demonstrate that such a shift in iceberg trajectories during glacial periods can result in a considerable redistribution of freshwater in the Southern Ocean. We suggest that this, in concert with increased sea-ice cover, enabled positive buoyancy anomalies to 'escape' into the upper limb of the AMOC, providing a teleconnection between surface Southern Ocean conditions and the formation of NADW. The magnitude and pacing of this mechanism evolved substantially across the mid-Pleistocene transition, and the coeval increase in magnitude of the 'southern escape' and deep circulation perturbations implicate this mechanism as a key feedback in the transition to the '100-kyr world', in which glacial-interglacial cycles occur at roughly 100,000-year periods.

Published
2021
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